Post on 17-Aug-2020
ION Pumps for UHV Systems, Synchrotrons & Particle Accelerators
Mauro Audi,
Academic, Government & Research Marketing Manager
Agilent Confidential
ION Pumps Agilent Technologies
December 16, 2015
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1957-59 Varian Associates invents the first ION Pump
Agilent Confidential
ION Pumps Main choice for UHV systems, synchrotron & particle accelerators Why?
December 16, 2015
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1.Closed pump Do not need any baking pump No contamination from the roughing line
2.No moving parts There is no rotation or moving parts
3.No lubricant There are no oil or solvents and is fully contamination free
4.Can withstand air inrush or improper use Maintenance free, High reliability
Agilent Confidential
ION Pumps Basic Pumping Mechanism
December 16, 2015
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Pumping principle:
• Plasma discharge in crossed electric and magnetic field act as an electron trap
• Ionizing collision between electron and gas • Ion bombardment of titanium cathode • Some ions diffuse into the cathode ( pumped ) • Sputtering of chemically active Ti film on anode • Neutral Gas molecules stick to Ti film (chemisorption)
and are buried in the anode ( main pumping) • Ion pumps do not pump ions at the cathode , but
neutral molecules at the anode
Agilent Confidential
ION Pumps Basic Pumping Mechanism – Noble gases
December 16, 2015
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• This works only for all active (getterable) gases • Noble gases do not react with Ti film • No chemisorption of neutral molecules • Some ion bombarding the cathode are neutralized and reflected • Some of them maintain enough energy to be physically implanted into the anode • They will then be covered by the sputtered Ti film • It is a physical burying, not a chemical reaction • Pumping much less efficient than for getterable gases
Agilent Confidential
ION Pumps
December 16, 2015
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Pure Argon Air (1% Ar)
10 E-5 mbar 8 days
10 E-6 mbar 20 hours 3 months
10 E-7 mbar 8 days 2.5 years
10 E-8 mbar 3 months 25 years
10 E-9 mbar 2.5 years
Diode Ion Pump
Highest pumping speed for all getterable gases (H2, CO, CO2, N2, H2O) Highest pumping speed at low pressures Limited speed (5 to 10%) and low capacity when pumping noble gases such as Argon, Helium The only reason for different and more expensive ion pumps is to improve pumping speed and stability for Noble Gases
Limited Argon capacity means:
Agilent Confidential
December 16, 2015
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ION Pumps Diode
Diode pumps can work for 20 years before Argon instability
In UHV application, where: • Ion pumps are started below 1E-6 mbar • The system is rarely vented to air • There are no air leaks • The ion pump is used to pump the outgassing of the
vacuum chamber • The Pressure is lower than 1E -8 mbar
Agilent Confidential
December 16, 2015
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However, in real life… • Air leaks may be present • Venting to air may be more frequent than desired • Working pressure may be higher than design values
ION Pumps Different types of pump: Diode, Noble Diode and StarCell
…then more Argon than expected has to be pumped ION Pumps with improved stability for noble gases may be a safer approach
Agilent Confidential
December 16, 2015
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Ion Pumps for Noble Gases design Improve the number/probability of Noble Gas ions reflection vs implantation after bombarding the catodo After being reflected, they may be physically buried into the anode (no chemical interaction) Two different approaches to modify Diode to obtain this result:
ION Pumps Different Noble Diode & StarCell vs Diode
Both solutions do improve the pumping speed and stability for noble gases
Agilent Confidential
December 16, 2015
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Noble Diode vs Diode • Much lower capacity and speed for H2 • Lower speed for all getterable gases (N2, CO, CO2) • Improved stability and speed for Noble Gases (factor
up to 10 - 20 times) • Argon speed up to 15% 20% of Air Pumping speed
ION Pumps Noble Diode & StarCell vs Diode
Starcell vs Diode • Lower speed for all getterable gases (N2, CO, CO2) • Comparable speed for Hydrogen • Improved speed and stability for Noble Gases (up to 50 – 100 times) • Argon speed up to 35% 40% of Air Pumping speed • When only getterable gases must be pumped, Diode is still the best choice
Agilent Confidential
December 16, 2015
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• Much higher capacity for H2 (one order of magnitude)
• Similar speed for all getterable gases (N2, CO, CO2)
• Higher stability for Noble Gases (factor of 5 to 10 times)
• Higher speed for Noble Gases (almost double , up to 40 % vs 20% of Air)
• When Noble gases must be pumped , StarCell is the proper choice
ION Pumps StarCell vs Noble Diode
Agilent Confidential
December 16, 2015
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ION Pumps How to choose the correct ion pump
1.Operation mode • Venting frequency • Starting pressure (roughing pumps) 2.Gases • Noble Gases (He, Ar, Kr, Xe...) • Getterable Gases
Essential parameters of a UHV system
3.Size of the chamber • Surface exposed to vacuum • Outgassing • Conductance
4.Base Pressure • Ion pump alone • Combination with TSP or NEG
Agilent Confidential
December 16, 2015
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ION Pumps Agilent Ion Pumps elements comparison table 1/2
Agilent Confidential
December 16, 2015
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ION Pumps Agilent Ion Pumps elements comparison table 2/2
CERN Geneva Switzerland
Agilent Confidential
December 16, 2015
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ION Pumps Specific design for Large UHV Systems, Synchrotron & Particle Accelerator
Pumping speed is not the most important parameter to reach UHV• outgassing • contamination • vacuum leaks (corrosion)
…may be more critical than pumping speed for large UHV systems, i.e. Synchrotron
Agilent Confidential
December 16, 2015
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ION Pumps Specific design for Synchrotron & Particle Accelerator
Pump designed to minimize outgassing/contamination
1.Material choice 2.Material cleaning 3.Pump process
HV feedthrough and HV cable designed radiation and corrosion proof to avoid potential problems (leaks)
Agilent Confidential
December 16, 2015
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ION Pumps Specific design for Synchrotron & Particle Accelerator
Material choice
• Only UHV compatible materials: Metals and Ceramic
• Body, Flange, Anode : Stainless Steel 304 or 316, L or LN 1.L, low C precipitation, better corrosion
resistance 2.LN, Nitrogen for improved mechanical
resistance • Cathode: Titanium grade A (Tantalum) • Insulators: Alumina Al2 O3
• Degreasing in Alkaline bath (NaOH-Na2CO3) • Ultrasonic degreasing in Alkaline bath • Cold rinsing • Cold rinsing with deionized water • Pickling, in Nitric and Fluoridric acid bath (HF-
HNO3) • Cold rinsing • Cold rinsing with deionized water • Hot rinsing with deionized water • Oven drying at 150°C
Material Cleaning
Agilent Confidential
December 16, 2015
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ION Pumps Manufacturing
• The ion pump element must be the cleanest surface exposed to vacuum , because its outgassing is due to both thermal and bombardment induced effect
• The surface will eventually be removed (sputtered): not only the surface , but the bulk too must be hydrogen free
• Ion pump element is “vacuum fired” @ 950 °C • Then, the complete pump is processed under
vacuum at 450°C
Agilent Confidential
December 16, 2015
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ION Pumps Manufacturing
• Pumps are individually processed • Residual gas analysis for each pump • Individual records of each pump ( outgassing ,
spectra…) • Pumps are processed in nitrogen atmosphere
to prevent external oxidation (no more beadblasting needed)
• Pumps can be leak-checked at high temperature (Helium instead of Nitrogen)
• Vacuum performance are much more repeatable
Agilent Confidential
December 16, 2015
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ION Pumps Manufacturing - RGA
Vacuum Side Brazing for Corrosion Free
Agilent Confidential
December 16, 2015
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ION Pumps Corrosion free• Corrosion free feedthrough • HV feedthrough and connector are
subjected to corrosion • Transition metal to Kovar (or similar)
to ceramic is critical • Temperature cycling , humidity , high
electric field gradient may cause corrosion
• Water vapor trapped in between the connector and the feedthrough may cause oxidation
• Specific design to minimize air trapping and critical surface exposed to air (vacuum side brazing)
Agilent Confidential
December 16, 2015
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ION Pumps Safety Interlock
From passive to active safety Passive Safety • The control unit and HV cable
connector must be intrinsically safe • No live parts can be touched Active Safety • Interlock on HV connection to ensure
that HV is switched off whenever the HV cable is disconnected, either from the pump or from the controller
Safety Interlock Contacts
Agilent Confidential
December 16, 2015
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ION Pumps Controller Design to Optimize Pump Performances in the Entire Operating Pressure Range Summary
• Little efforts dedicated in the recent past to IP controller developments • Properly Designed Ion Pump controller maximizes IP performances in the entire operating range • Variable voltage maximizes pumping speed • Variable voltage allows reliable pressure reading at low pressures • Power control ensure starting at «high» pressure with limited power and low «aging» of the ion pump • State of the art controllers incorporate all these functions in a compact and light design
Agilent Confidential
December 16, 2015
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Variable Voltage Optimizes Ion Pump Pumping SpeedPumping Speed vs. Applied Voltage
Ion bombarding energy of approx 3 keV ensure efficient sputtering Space charge effect reduces ion energy • Space charge effect is a function of pressure • At «0» pressure ion energy equals applied voltage • Marginal reduction at UHV condition , major effect at higher pressures • In the 10-9 mbar range approx 3 kV are sufficient to ensure 3 keV of actual ion energy • In the 10-5 mbar range approx 7 kV are needed to ensure 3 keV of actual ion energy
Agilent Confidential
December 16, 2015
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Variable Voltage Optimizes Ion Pump Pumping SpeedPumping Speed vs. Applied Voltage
Agilent Confidential
December 16, 2015
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ION Pumps Pressure measurement
• An Ion Pump is a Penning cell, Ion Current Proportional to Pressure • IP Parameters (V , B , cell dimensions) optimized for pumping, not for pressure reading • Current reading may be affected by Field Emission Current (independent of pressure) • Total current (Ion + FE) conversion into pressure may be questionable • FE current effect is dominant when Ion current is very low (Low p) and negligible when Ion
current is high (High p) • FE current is an exponential function of Voltage • Lowering V at low pressures minimizes the FE current and allows a reilable current to
pressure conversion
Agilent Confidential
December 16, 2015
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ION Pumps Field Emission (leakage) current effect
Agilent Confidential
December 16, 2015
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ION Pumps Field Emission (leakage) current effect